Efficient computation of exposure profiles for counterparty credit risk

Cornelis S.L. De Graaf; Qian Feng; Drona Kandhai; Cornelis W. Oosterlee

doi:10.1142/S0219024914500241

Efficient computation of exposure profiles for counterparty credit risk

Cornelis S.L. De Graaf, Qian Feng, Drona Kandhai, Cornelis W. Oosterlee

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Three computational techniques for approximation of counterparty exposure for financial derivatives are presented. The exposure can be used to quantify so-called Credit Valuation Adjustment (CVA) and Potential Future Exposure (PFE), which are of utmost importance for modern risk management in the financial industry, especially since the recent credit crisis. The three techniques all involve a Monte Carlo path discretization and simulation of the underlying entities. Along the generated paths, the corresponding values and distributions are computed during the entire lifetime of the option. Option values are computed by either the finite difference method for the corresponding partial differential equations, or the simulation-based Stochastic Grid Bundling Method (SGBM), or by the COS method, based on Fourier-cosine expansions. In this research, numerical results are presented for early-exercise options. The underlying asset dynamics are given by either the Black-Scholes or the Heston stochastic volatility model.

Original language	English
Article number	1450024
Journal	International Journal of Theoretical and Applied Finance
Volume	17
Issue number	4
DOIs	https://doi.org/10.1142/S0219024914500241
Publication status	Published - Jun 2014
Externally published	Yes

Bibliographical note

Funding Information:
The authors would like to thank Shashi Jain for helpful advice regarding the SGBM method and Dr. Norbert Hari for fruitful discussions about the FDMC method. Furthermore, the financial support by the Dutch Technology Foundation STW (project 12214) is greatfully acknowledged.

Funding

The authors would like to thank Shashi Jain for helpful advice regarding the SGBM method and Dr. Norbert Hari for fruitful discussions about the FDMC method. Furthermore, the financial support by the Dutch Technology Foundation STW (project 12214) is greatfully acknowledged.

Keywords

Bermudan options
Expected exposure
finite differences
Heston
numerical computation
potential future exposure
stochastic grid bundling method

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title = "Efficient computation of exposure profiles for counterparty credit risk",

abstract = "Three computational techniques for approximation of counterparty exposure for financial derivatives are presented. The exposure can be used to quantify so-called Credit Valuation Adjustment (CVA) and Potential Future Exposure (PFE), which are of utmost importance for modern risk management in the financial industry, especially since the recent credit crisis. The three techniques all involve a Monte Carlo path discretization and simulation of the underlying entities. Along the generated paths, the corresponding values and distributions are computed during the entire lifetime of the option. Option values are computed by either the finite difference method for the corresponding partial differential equations, or the simulation-based Stochastic Grid Bundling Method (SGBM), or by the COS method, based on Fourier-cosine expansions. In this research, numerical results are presented for early-exercise options. The underlying asset dynamics are given by either the Black-Scholes or the Heston stochastic volatility model.",

keywords = "Bermudan options, Expected exposure, finite differences, Heston, numerical computation, potential future exposure, stochastic grid bundling method",

author = "{De Graaf}, {Cornelis S.L.} and Qian Feng and Drona Kandhai and Oosterlee, {Cornelis W.}",

note = "Funding Information: The authors would like to thank Shashi Jain for helpful advice regarding the SGBM method and Dr. Norbert Hari for fruitful discussions about the FDMC method. Furthermore, the financial support by the Dutch Technology Foundation STW (project 12214) is greatfully acknowledged.",

year = "2014",

month = jun,

doi = "10.1142/S0219024914500241",

language = "English",

volume = "17",

journal = "International Journal of Theoretical and Applied Finance",

issn = "0219-0249",

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AU - De Graaf, Cornelis S.L.

AU - Feng, Qian

AU - Kandhai, Drona

AU - Oosterlee, Cornelis W.

N1 - Funding Information: The authors would like to thank Shashi Jain for helpful advice regarding the SGBM method and Dr. Norbert Hari for fruitful discussions about the FDMC method. Furthermore, the financial support by the Dutch Technology Foundation STW (project 12214) is greatfully acknowledged.

PY - 2014/6

Y1 - 2014/6

N2 - Three computational techniques for approximation of counterparty exposure for financial derivatives are presented. The exposure can be used to quantify so-called Credit Valuation Adjustment (CVA) and Potential Future Exposure (PFE), which are of utmost importance for modern risk management in the financial industry, especially since the recent credit crisis. The three techniques all involve a Monte Carlo path discretization and simulation of the underlying entities. Along the generated paths, the corresponding values and distributions are computed during the entire lifetime of the option. Option values are computed by either the finite difference method for the corresponding partial differential equations, or the simulation-based Stochastic Grid Bundling Method (SGBM), or by the COS method, based on Fourier-cosine expansions. In this research, numerical results are presented for early-exercise options. The underlying asset dynamics are given by either the Black-Scholes or the Heston stochastic volatility model.

AB - Three computational techniques for approximation of counterparty exposure for financial derivatives are presented. The exposure can be used to quantify so-called Credit Valuation Adjustment (CVA) and Potential Future Exposure (PFE), which are of utmost importance for modern risk management in the financial industry, especially since the recent credit crisis. The three techniques all involve a Monte Carlo path discretization and simulation of the underlying entities. Along the generated paths, the corresponding values and distributions are computed during the entire lifetime of the option. Option values are computed by either the finite difference method for the corresponding partial differential equations, or the simulation-based Stochastic Grid Bundling Method (SGBM), or by the COS method, based on Fourier-cosine expansions. In this research, numerical results are presented for early-exercise options. The underlying asset dynamics are given by either the Black-Scholes or the Heston stochastic volatility model.

KW - Bermudan options

KW - Expected exposure

KW - finite differences

KW - Heston

KW - numerical computation

KW - potential future exposure

KW - stochastic grid bundling method

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DO - 10.1142/S0219024914500241

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SN - 0219-0249

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JO - International Journal of Theoretical and Applied Finance

JF - International Journal of Theoretical and Applied Finance

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ER -

Efficient computation of exposure profiles for counterparty credit risk

Abstract

Bibliographical note

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Keywords

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